basic electricity parameters
DESCRIPTION
basic electricity parameters and accidentsTRANSCRIPT
Welcome to the Presentation on
Basics of ElectricityElectricity Parameters
Provisions and Requirements related to Safety
Safety, Accident Prevention & Disaster Management
(SAFETY)
BASICS OF ELECTRICITY Elements of an Atom :
All matter is made up atoms. Atoms have a nucleus with electrons in motion around
it. The nucleus is composed of protons and neutrons . Electrons have a negative charge (-). Protons have a positive charge (+). Neutrons are neutral. In the normal state of an atom, the number of electrons
is equal to the number of protons and the negative charge of the electrons is balanced by the positive charge of the protons.
Free Electrons: Electrons move about the nucleus at different
distances. The closer to the nucleus, the more tightly bound the
electrons are to the atom. Electrons in the outer band can be easily forced out of
the atom by the application of some external force such as a magnetic field, friction, or chemical action.
Electrons forced from atoms are sometimes called free electrons.
Electrons in the outer band of an atom can be easily displaced by the application of external force.
A free electron leaves a void which can be filled by an electron forced out of another atom.
CURRENT The flow of free electrons in a material from one atom to
the next atom in the same direction is referred to as current and is designated by the symbol I.
The amount of current flowing is determined by the number of electrons that pass through a cross-section of a conductor in one second. current is measured in amperes, often shortened to amps.
The letter A is the symbol for amps. A current of one amp means that in one second about 6.24
x 1018 electrons move through a cross-section of conductor.
VOLTAGE The force required to make electricity flow through a
conductor is called a difference in potential, electromotive force (emf),or voltage.
Voltage is designated by the letter E or the letter V. The unit of measurement for voltage is the volt which is
also designated by the letter V. A voltage can be generated in various ways. A battery uses an electrochemical process. A car’s alternator and a power plant generator utilize a
magnetic induction process. All voltage sources share the characteristic of an excess
of electrons at one terminal and a shortage at the other terminal.
This results in a difference of potential between the two terminals.
For a direct current (DC) voltage source, the polarity of the terminals does not change, so the resulting current constantly flows in the same direction.
RESISTANCE A third factor that plays a role in an electrical circuit is resistance.
All material impedes the flow of electrical current to some extent.
The amount of resistance depends upon the composition, length, cross-section and temperature of the resistive material.
As a rule of thumb, the resistance of a conductor increases with an increase of length or a decrease of cross-section.
Resistance is designated by the symbol R.
The unit of measurement for resistance is the ohm.
ELECTRIC CIRCUIT A simple electric circuit consists of a voltage source, some type of load,
and conductors to allow electrons to flow between the voltage source and the load.
Ohm’s law shows that current varies directly with voltage and inversely with resistance.
Current (I) is measured in amperes (amps) ,Voltage (E) is measured in volts and Resistance (R) is measured in ohms.
There are three ways to express Ohm’s law
I = E /R E =I*R R=E/I
POWER IN A DC CIRCUIT Whenever a force of any kind causes motion, work is
accomplished. If a force is exerted without causing motion, then no work is
done. In an electrical circuit, voltage applied to a conductor causes
electrons to flow. Voltage is the force and electron flow is the motion. Power is the rate at which work is done and is represented by
the symbol P. The unit of measure for power is the watt, represented by the
symbol W. In a direct current circuit, one watt is the rate at which work
is done when 1 volt causes a current of 1 amp. From the basic formula power = current *voltage.
ALTERNATING CURRENT The supply of current for electrical devices may come from
a direct current (DC) source or an alternating current (AC) source.
In a direct current circuit, electrons flow continuously in one direction from the source of power through a conductor to a load and back to the source of power.
Voltage polarity for a direct current source remains constant.
DC power sources include batteries and DC generators. By contrast, an AC generator makes electrons flow first in
one direction, then in another. In fact, an AC generator reverses its terminal polarities
many times a second, causing current to change direction with each reversal.
AC SINE WAVE Alternating voltage and current vary continuously.
The graphic representation for AC is a sine wave.
A sine wave can represent current or voltage.
There are two axes.
The vertical axis represents the direction and magnitude of current or voltage.
The horizontal axis represents time.
When the waveform is above the time axis, current is flowing in one direction. This is referred to as the positive direction.
AC SINE WAVE
When the waveform is below the time axis, current is flowing in the opposite direction. This is referred to as the negative direction.
A sine wave moves through a complete rotation of 360 degrees, which is referred to as one cycle.
Alternating current goes through many of these cycles each second.
AMPLITUDE As previously discussed, voltage and current in an AC
circuit rise and fall over time in a pattern referred to as a sine wave.
In addition to frequency, which is the rate of variation, an AC sine wave also has amplitude, which is the range of variation. Amplitude can be specified in three ways: peak value, peak-to peak value, and effective value.
Effective value (also called RMS value) = Peak Value x 0.707
INDUCTANCE Inductance is the property of an electric circuit that
opposes any change in electric current. Resistance opposes current flow, inductance opposes
changes in current flow. Inductance is designated by the letter L. The unit of measurement for inductance is the henry (h); However, because the henry is a relatively large unit,
inductance is often rated in millihenries or microhenries. All conductors and many electrical devices have a
significant amount of inductance, but inductors are coils of wire wound for a specific inductance.
For some applications, inductors are wound around a metal core to further concentrate the inductance.
The inductance of a coil is determined by the number of turns in the coil, the coil diameter and length, and the core material.
As shown in the following illustration, an inductor is usually indicated symbolically on an electrical drawing as a curled line.
CAPACITANCE AND CAPACITORSCapacitance is a measure of a circuit’s ability to store
an electrical charge. A device manufactured to have a specific amount of
capacitance is called a capacitor. A capacitor is made up of a pair of conductive plates
separated by a thin layer of insulating material. Another name for the insulating material is dielectric
material. A capacitor is usually indicated symbolically on an
electrical drawing by a combination of a straight line with a curved line or two straight lines.
When a voltage is applied to the plates of a capacitor, electrons are forced onto one plate and pulled from the other.
This charges the capacitor. Direct current cannot flow through the dielectric material
because it is an insulator; However, the electric field created when the capacitor is
charged is felt through the dielectric. Capacitors are rated for the amount of charge they can
hold.
The capacitance of a capacitor depends on the area of the plates, the
distance between the plates, and type of dielectric material used.
The symbol for capacitance is C and the unit of measurement is the farad
(F).
However, because the farad is a large unit, capacitors are often rated in
microfarads (F) or picofarads (pF).
The capacitance of a capacitor depends on the area of the plates, the
distance between the plates, and type of dielectric material used.
The symbol for capacitance is C and the unit of measurement is the farad
(F).
However, because the farad is a large unit, capacitors are often rated in
microfarads (F) or picofarads (pF).
ELECTRICITY PARAMETERS RELATED TO SAFETY
• Use of electricity is so widespread that there may be hardly anyone who has not experienced a slight electric shock at one time or other.
• Voltages (of a circuit) cause currents to pass through any resistance.
• The resistance of the human body at best is of the order of 9000 ohms and at the worst is 500 ohms.
• A major part of the resistance is due to the skin.
• The internal resistance of the body varies from 200 to 800 ohms. So, when the skin is wet and when perspiring freely, the body resistance is at its worst.
• In shocks from AC currents of normal power frequency, the shock
current is sinusoidal with frequency of 50 Hz.
• The AC shock current frequency disturbs the frequency of heart signals.
• Also, Direct Current, normally known as D.C. is four times safer than A.C.
• That is body resistance is four times more than what is mentioned earlier
when D.C is used instead of A.C.
• In Calcutta, if you ask an elderly washer man whether he likes A.C. or D.C.
iron he will invariable say D.C. If you ask him for the reason, he will say
that A.C. catches you in case of shock where as D.C. gives only a mild
shock.
EFFECT OF CURRENT
• Human body gets electric shock when current passes through any part
of the body due to applied voltage difference across that part.
• Severity of shock depends on how much current is flowing and path of
current through the body and how much time duration.
• If the path involves the heart, the damage is more. If the path is
through the left hand to earth, the heart will invariably get involved.
• Before considering the effect of the magnitude of current on the human
body, certain fundamentals regarding voltage and current need to be
cleared by a simple example.
Example
Normal voltage 230 volts A.C.
Resistance due to footwear and body
resistance. Say
69000 ohms.
Then current = Voltage/Resistance 230/69000
= 0.0033 Amps
Now 1 Amp
= 1000 milli Amps or mA
So current through the body
= .0033 Amps = 3.3 mA
Effects of various values of current on the body are as follows
Value of
Current in
milli Amps
Duration
of shock
Physiological effect on humans
Up to 1 mA Not critical Range up to threshold of perception,
1-15 mA Not critical Range up to threshold of cramp.
Independent release of hands from
object gripped no longer possible, i.e.
beyond “let-go” range. Sometimes
painful effect on muscles of fingers and
arms.
15-30 mA few seconds Cramp like contraction of
arms. Difficulty in
breathing. Rise in blood
pressure.
30-50 mA few seconds Heart irregularities.
Powerful cramp effect.
Unconsciousness. Rise in
blood pressure. If time
runs to minutes, may
prove fatal.
50 to a few
hundreds
Less than cardiac
cycle
No ventricular fibrillation.
Heavy shock.
50 to a few hundreds Above one cardiac
cycle
Ventricular fibrillation.
Current marks.
Unconsciousness. If not
attended immediately –
death.
Above a few
hundreds
Less than cardiac
cycle
Ventricular fibrillation
possible depending on
heart phases. Current
marks. Unconsciousness.
Above a few
hundreds
Over one cardiac
cycle
Reversible cardiac arrest.
Unconsciousness burns.
GENERAL PROVISIONS RELATING TO SAFETY
Statutory Regulations
• The electricity supply undertakings are required to comply with the following statutory Acts, besides Electricity Act 2003
• Factories Act, 1948; and
• Workmen Compensation Act,1923.
• Payment of Wages Act, 1936
• It shall be the responsibility of the person-in-charge to interpret and explain correctly the rules and regulations to all the staff concerned and to ensure that the staff thoroughly understands the same.
DEFINITIONS
• ‘APPROVED’ means a type sanctioned for use by the undertaking.
• ‘AUTHORISED PERSON’ means a competent person appointed in
writing by a competent authority to carry out specific duties incidental
to the transmission, conversion, transformation, distribution or
utilization of electrical energy as per the provisions of Rules.
• ‘COMPETENT PERSON’ means a person who has sufficient technical
knowledge and / or experience of a particular branch of engineering or
science and is normally of the rank of not lower then Executive
Engineer.
• EARTH’ means the conducting mass of earth or a conductor connected
to it through very small impedance.
• ‘ELECTRICAL APPARATUS’ means all electrical apparatus pertaining to
the transmission, distribution and utilization of electrical energy.
• ‘ISOLATED’ means physically disconnected from all sources of
electrical energy and in manner that disconnected contacts of the
isolating switch are normally visible.
• ‘LIVE’ in respect of any apparatus, equipment and conductor means
electrically charged.
• MECHANICAL EQUIPMENT’ means all mechanical equipment
pertaining to the transmission, distribution and utilization of electrical
energy.
• ‘PERMIT TO WORK’ means a form of declaration issued by an
Authorized Person to another Authorized Person-in-charge of the work
to be carried out on or adjacent to any electrical apparatus or chemical
equipment for the purpose of making known to such latter person
exactly what apparatus or equipment have been made dead, isolated
and discharged are safe to be worked on, and gives the description of
the work required to be carried out under the permit.
• ‘TEMPORARY EARTH’ means an earth defined under Para above, but
applied temporarily at the point of work on any electrical apparatus
during actual working thereon after the issue of Permit to Work.
• ‘VISITOR’ means a person other than an employee permitted to enter a
work point under a permit by the undertaking.
GENERAL CONDITIONS RELATING TO SUPPLY AND USE OF ELECTRICITY
Precautions against leakage before connection
The supplier shall not connect with his works the installation or
apparatus on the premises of nay applicant for supply unless he is
reasonably satisfied that the connection will not at the time of making
the connection cause a leakage from the installation or apparatus of a
magnitude detrimental to safety which shall be checked by measuring
the insulation resistance as under-
• All equipments shall have the insulation resistance (IR) value as
stipulated in the relevant Indian Standards.
• On application of 500 V DC between each live conductor and earth for
a period of one minute, the insulation resistance of installation and
equipment of voltage not exceeding 650 V shall be at least 1 MEGA
OHM or as specified in the relevant Indian Standards.
• On application of 2.5 kV DC between each live conductor and earth for
a period of one minute, the insulation resistance of installation and
equipment of voltage exceeding 650 V but not exceeding 33 KV shall be
at least 5 MEGA OHM or as specified in the relevant Indian Standard.
LEAKAGE ON CONSUMER’S PREMISES
• If the Electrical Inspector or the supplier has reasons to believe that
there is leakage in the system of a consumer which is likely to affect
injuriously the use of electricity by the supplier or by other persons, or
which is likely to cause danger, he may give the consumer a notice in
writing that he desires to inspect and test the consumer's installation.
SUPPLY AND USE OF ELECTRICITY
• The electricity shall not be supplied, transformed, converted, inverted
or used or continued to be supplied, transformed converted, inverted
or used unless the conditions contained in sub-regulations
• The following controls of requisite capacity to carry and break the
current shall be placed as near as possible after the point of
commencement of supply so as to be readily accessible and capable of
being easily operated to completely isolate the supply to the
installation, such equipment being in addition to any equipment
installed for controlling individual circuits or apparatus, namely.
• A linked switch with fuse or a circuit breaker by consumers of voltage
which does not exceed 650 V;
• A linked switch with fuse or a circuit breaker by a consumer of
voltage exceeding 650 V but not exceeding 33 kV having aggregate
installed transformer or apparatus capacity up to 1000 KVA to be
supplied at Voltage up to 11 kV and 2500 KVA at higher voltages
(above 11 kV and not exceeding 33 kV);
• A circuit breaker by consumers at voltage exceeding 650 V but not
exceeding 33 kV having an aggregate installed transformer and
apparatus capacity above 1000 KVA and supplied at voltage up to 11
kV and above 2500 KVA at higher voltages (above 11 kV and not
exceeding 33 kV).
• A circuit breaker by a consumer of voltage exceeding 33 kV.
• Provided that where the point of commencement of supply and the
consumer apparatus are near each other, one linked switch with fuse
or circuit breaker near the point of commencement of supply shall be
considered sufficient.
• In case of every transformer the following shall be provided; namely
• On primary side for transformers, a linked switch with fuse or circuit
breaker of adequate capacity
• Provided that the linked switch on the primary side of the transformer
may be of such capacity as to carry the full load current and to break
only the magnetizing current the transformer
Provided further that for all transformers
• Having a capacity of 5000 KVA and above installed before the year
2000; and
• Having a capacity 1000 KVA and above installed in or after the year
2000, a circuit breaker shall be provided
• Provided also that the linked switch on the primary side of the
transformer shall not require for the unit auxiliary transformer and
generator transformer
• In respect of all transformers installed in or after the year 2000, on the
secondary side of all transformers, a circuit breaker of adequate rating
shall be installed
• Provided that for Suppliers’ of transformers of capacity below 1000
KVA, a linked switch with fuse or circuit breaker of adequate rating
shall be installed on secondary side.
• Except in the case of composite control gear designed as a unit each
distinct circuit is to be protected against excess energy by means of
suitable cut-out or a circuit breaker of adequate breaking capacity
suitably located and so constructed as to prevent danger from
overheating, arcing or scattering of hot metal when it comes into
operation and to permit for ready renewal of the fusible metal of the
cut-out without danger.
• The supply of electricity to each motor or a group of motors or other
apparatus meant for operating one particular machine shall be
controlled by a suitable linked switch or a circuit breaker or an
emergency tripping device with manual reset of requisite capacity
placed in such a position as to be adjacent to the motor or a group of
motors or other apparatus readily accessible to and easily operated by
the person in charge and so connected in the circuit that by its means
all supply of electricity can be cut off from the motor or group of
motors or apparatus from any regulating switch, resistance of other
device associated therewith.
• All insulating materials shall be chosen with special regard to the
circumstances of their proposed use and their mechanical strength
shall be sufficient for their purpose and so far as is practicable of such
a character or so protected as to maintain adequately their insulating
property under all working conditions in respect of temperature and
moisture.
• Adequate precautions shall be taken to ensure that no live parts are so
exposed as to cause danger.
• Every consumer shall use all reasonable means to ensure that where
electricity is supplied by a supplier, no parson, other than the supplier
shall interfere with service lines and apparatus placed by the supplier
on the premises of the consumer.
PROVISIONS FOR SUPPLY AND USE OF
ELECTRICITY IN MULTI – STOREYED
BUILDING MORE THAN 15 METERS IN HEIGHT
• The connected load and voltage of supply above which inspection is to
be carried out by an Electrical Inspector for a multi-storeyed building
of more than fifteen meters height shall be notified by the Appropriate
Government.
• Before making an application for commencement of supply or
recommencement of supply after an installation has been disconnected
for a period of six months or more, the owner or occupier of a multi-
storeyed building shall give not less than thirty days notice in writing
to the Electrical Inspector specify therein the particulars of
installations and the supply of electricity shall not be commenced or
recommenced within this period, without the approval in writing of
the Electrical Inspector.
• The supplier or owner of the installation shall provide at the point of
commencement of supply a suitable iso1ating device with cut-out or
breaker to operate on all phases except neutral in the 3 phase, 4-wire
circuit and fixed in a conspicuous position at not more than 1.70
meters above the ground so as to completely isolate the supply to the
building in case of emergency.
• The owner or occupier of a multi- storeyed building shall ensure that
electrical installations and works inside the building are carried out
and maintained in such a manner as to prevent danger due to shock
and fire hazards, and the installation is carried out in accordance with
the relevant codes of practice.
• No other service pipes and cables shall be taken along the ducts
provided for laying power cables and all ducts provided for power
cab1es and other services shall be provided with fire barrier at each
floor crossing.
CONDITIONS APPLICABLE TO INSTALLATIONS OF VOLTAGE EXCEEDING 250 VOLTS
• The following conditions shall be complied with where electricity of
voltage above 250 V is supplied, converted, transformed or used;
namely
Contd:
• All conductors, other than those of overhead lines, shall be completely
enclosed in mechanically strong metal casing or metallic covering
which is electrically and mechanically continuous and adequately
protected against mechanical damage unless the said conductors are
accessible only to an designated person or installed and protected so
as to prevent danger: provided that non-metallic conduits conforming
to the relevant Indian Standard Specifications may be used for
installations of voltage not exceeding 650 V
• All metal works, enclosing supporting or associated with the
installation, other than that designed to serve as a conductor shall be
connected with an earthing system as per standards laid down in the
Indian Standards in this regard and the provisions of regulations.
• Every switchboard shall comply with the following
• A clear space of not less than one meter in width shall be provided in
front of the switchboard;
• If there are any attachments or bare connections at the back of the
switchboard, the space, if any, behind the switchboard shall be either
less than twenty centimeters or more than seventy five centimeters in
width, measured from the farthest protruding part of any attachment
or conductor.
• If the space behind the switchboard exceeds seventy five centimeters
in width, there shall be a passage way from either end of the
switchboard, clear to a height of 1.8 meters.
• In case of installations provided in premises where inflammable
materials including gases and chemicals are produced, handled or
stored, the electrical installations, equipment and apparatus shall
comply with the requirements of flame proof, dust tight, totally
enclosed or any other suitable type of electrical fittings depending
upon the hazardous zones as per the relevant Indian Standard
Specifications.
SAFETY PROVISIONS FOR ELECTRICAL INSTALLATIONS AND APPARATUS OF VOLTAGE
NOT EXCEEDING 650 VOLTS:Connection with earth
The following conditions shall apply to the connection with earth of
systems at voltage normally exceeding 125 V but not exceeding 650 V,
namely:
• Neutral conductor of a 3-phase, 4-wire system and the middle
conductor of a 2-phase, 3-wire system shall be earthed by not less than
two separate and distinct connections with a minimum of two different
earth electrodes or such large number as may be necessary to bring
the earth resistance to a satisfactory value both at the generating
station and at the sub-station.
• The earth electrodes so provided, shall be inter-connected to reduce
earth resistance.
• Neutral conductor shall also be earthed at one or more points along
the distribution system or service-line, in addition to any connection
with earth which may be at the consumer’s premises.
• In the case of a system comprising electric supply lines having
concentric cables, the external conductor of such cables shall be
earthed by two separate and distinct connections with earth.
• No person shall make connection with earth by the aid of, nor shall he
keep it in contact with, any water mains not belonging to him except
with the consent of the owner thereof and of the Electrical Inspector.
• Alternating current systems which are connected with earth as
aforesaid shall be electrically interconnected;
• Provided that each connection with earth is bonded to the metal
sheathing and metallic armoring, if any, of the electric supply lines
concerned.
• The frame of every generator, stationary motor, portable motor, and
the metallic parts, not intended as conductors, of all transformers and
any other apparatus used for regulating or controlling electricity, and
all electricity consuming apparatus, of voltage exceeding 250 V but not
exceeding 650 V shall be earthed by the owner by two separate and
distinct Connections with earth.
• Neutral point of every generator and transformer shall be earthed by
connecting it to the earthing system by not less than two separate and
distinct connections.
• All metal casing or metallic coverings containing or protecting any
electric supply line or apparatus shall be connected with earth and
shall be so joined and connected across all junction boxes and other
openings as to make good mechanical and electrical connection
throughout their whole length.
• Provided that conditions mentioned in this regulation shall not apply,
where the supply voltage does not exceed 250 V and the apparatus
consists of wall tubes or brackets, electroliers, switches, ceiling fans or
other fittings, other than portable hand lamps and portable and
transportable apparatus, unless provided with earth terminal and to
class - II apparatus and appliances.
• Provided further that where the supply voltage is not exceeding 250 V
and where the installations are either new or renovated;
all plug sockets shall be of the three pin type, and the third pin shall be
permanently and efficiently earthed.
EARTH LEAKAGE PROTECTIVE DEVICE
• The supply of electricity to every electrical Installation other than
voltage not exceeding 250 V below 5 kW and those installations of
voltage not exceeding 250 V which do not attract provisions of section
54 of the Act, shall be controlled by an earth leakage protective device
so as to disconnect the supply instantly on the occurrence of earth fault
or leakage of current.
• Provided that such earth leakage protective device shall not be
required for overhead supply lines having protective devices which are
effectively bonded to the neutral of supply transformers and
conforming to the relevant regulations.
SAFETY PROVISIONS FOR ELECTRICAL
INSTALLATIONS AND APPARATUS OF VOLTAGE
EXCEEDING 650 VOLTS
• The owner shall observe the following conditions, where electricity at
voltage exceeding 650 V is supplied, converted, transformed or used;
• He shall maintain safety clearances for electrical apparatus as per
Bureau of Indian Standard specification so that sufficient space is
available for easy operation and maintenance without any hazard to
the operating and maintenance personnel working near the equipment
and for ensuring adequate ventilation;
• He shall not allow any encroachment below such installation
Provided that where the Electrical Inspector comes across any such
encroachment, he shall direct the owner to remove such
encroachments
• The minimum safety working clearances specified in Schedule-VII shall
be maintained for the bare conductors or live parts of any apparatus in
outdoor sub-stations excluding overhead lines of installations of
voltage exceeding 650 V.
• He shall ensure that the windings of motors or other apparatus within
reach from any position in which a person may require to be, are
suitably protected so as to prevent danger.
• He shall ensure that where a transformer or transformers are used,
suitable provision shall be made, either by connecting with earth, a
point of the circuit at the lower voltage or otherwise, to guard against
danger by reason of the said circuit becoming accidentally charged
above its normal voltage by leakage from or contact with the circuit at
the higher voltage.
• A sub-station or a switching station with apparatus having more than
2000 liters of oil shall not be located in the basement where proper oil
draining arrangement cannot be provided.
Dry type of transformers only shall be used for installations inside the
residential and commercial buildings
• without prejudice to the above measures, he shall take adequate fire
protection arrangement for quenching the fire in the apparatus;
• He shall ensure that the transformers of 10 MVA and above rating or in
case of oil filled transformers with oil capacity of more than 2000
liters.
• Provided with fire fighting system as per IS - 3034: 1993 or with -
Nitrogen Injection Fire Protection System.
CONNECTION WITH EARTH FOR APPARATUS EXCEEDING 650V
All non-current carrying metal parts associated with an installation of
voltage exceeding 650 V shall be effectively earthed to a grounding
system or mat which shall,
• Limit the touch and step potential to tolerable values.
• Limit the ground potential rise to tolerable values so as to prevent
danger due to transfer of potential through ground, earth wires, cable
sheath, fences, pipe lines, etc.
• Maintain the resistance of the earth connection to such a value as to
make operation of the protective device effective.
In the case of star connected system with earthed neutrals or delta
connected system with earthed artificial neutral point,
• The neutral point of every generator and transformer shall be earthed
by connecting it to the earthing system not by less than two separate
and distinct connections.
Provided that the neutral point of a generator may be connected to the
earthing system through an impedance to limit the fault current to the
earth:
Provided further: that in the- case of multi-machine systems neutral
switching may be resorted to, for limiting the injurious effect of
harmonic current circulation in the system;
• Single phase systems of voltage exceeding 650 V shall be effectively
earthed.
• Every earthing system belonging to either the supplier or the
consumer shall be tested for its resistance to earth on a dry day during
dry season not less than once a year and records of such tests shall be
maintained.
GENERAL SAFETY PRACTICES IN ELECTRICAL WORK
Exercise care
Place yourself in a safe and secure position to avoid slipping, stumbling
or moving backward against live conductors or apparatus. Do not rely
for protection upon the care assumed to be exercised by others.
In the event of near approach of a lightning storm, all outdoor work on
electrical system should cease.
Make a habit of being cautious. Be on the lookout for danger notice
plates, danger flags, warning boards and signals etc. Warn others when
they seem to be in danger near live conductors or apparatus.
Personal apparel
Use of overalls, dungarees, jumpers and coats having metal buttons,
metals straps and similar metal fittings should be avoided. Bone
buttons may be used. Buttons should be sewed in place with thread.
Loose clothing should not be worn.
While working on live conductors, do not roll up sleeves as dry cloth
gives some protection against shocks.
Do not wear shoes with nailed soles. Shoes should have sewn soles, or
preferably rubber soles.
Do not wear suspenders and arm bands with metal buckles or other
metal parts. These might come in close proximity to live parts and
cause serious, if not fatal, injury.
Metal key chains or metal keepers for key rings or watch chains should
not be worn on the outside of clothing.
While welding, wear goggles, safety glasses or any other eye protection
as instructed by the person-in-charge depending upon the type of
work handled.
Treat everything as live
Treat all electrical conductors and apparatus always as live and
consequently dangerous to human life, unless it is positively known to
be dead and properly earthed and take precautions accordingly.
Never speak to any person working upon live mains or apparatus,
unless the person doing the work is aware of your presence.
Dangerous voltages
All voltages are dangerous. It shall be borne in mind that even low
voltage shock may be fatal.
Every person-in-charge of work on any mains or apparatus shall
assure himself that the same is free from dangerous leakage or
induction and has been effectively earthed locally before permitting
men to work upon it.
Dangerous areas
• When working in areas which contain or may contain live mains and
apparatus, fix danger notice plates, barriers, rails or other guarding
arrangement for the working area.
• Do not store materials within high voltage enclosures or low voltage
areas.
Warning boards
• Warning boards shall be placed by the person-in-charge on all
switchgear before men are permitted to work and should only be
removed by the person who has placed them.
• It is desirable that the person issuing the permit shall place one
warning board on the switch energizing the mains for each permit
issued so that he can be sure that all the permits-to-work are returned
when he has to charge the mains.
Visitors and un-authorized persons
• Visitors and unauthorized persons shall not be allowed to proceed in
the vicinity of live mains and apparatus, unless accompanied by an
authorized person who will be responsible to ensure that his
instructions regarding safety are strictly complied with.
Working in damp situations
• Extra precautions should be taken when working in abnormally damp
area.
Use of tong or clip-on ammeters
• These shall not be used on high voltage conductors, unless the
conductors are lead-sheathed. On low voltage conductors, all persons
not accustomed to the handling of tong or clip-on ammeter shall be
warned by the person instructing him of the necessary precautions to
be observed before being allowed to use it.
Warning the public
• When, either accidentally or otherwise, live mains and apparatus
constitute a danger to persons in a public place, a person shall be
detailed to stand by and personally warn the public until the danger
has been removed.
PORTABLE ELECTRICAL APPARATUS
• All portable electrical apparatus shall be regularly examined, tested
and maintained to ensure that the apparatus and leads are in good
order.
• Ensure that all portable appliances are provided with 3-pin plug and
socket connections and that the metal work of the apparatus is
effectively earthed.
• All loose wiring, such as flexible cables for portable lamps, tools and
trailing cables and other portable and transportable apparatus shall be
tested regularly at frequent intervals to ensure safety.
Lighting
• Inadequate lighting of working areas is by itself a source of danger,
particularly when work is undertaken at night. Never, therefore, allow
any work in dark or badly illuminated or ill-ventilated places.
Safety posters
• Suitable safety posters in the form of DOs and DON’Ts instructions for
the guidance of the working staff should be exhibited at important
locations, such as generating stations, receiving stations, sub-stations
and factories.
General Requirements Of Safety SAFETY REQUIREMENTS OF OVERHEAD LINESMaterial and strength: • All conductors of overhead lines shall have a breaking strength of
not less than 350 Kg. • Where the voltage does not exceed 250 V and the span is of less
than fifteen metres and is drawn through the owner’s or consumer’s premises, a conductor having an actual breaking strength of not less than 150 kg may be used.
Joints: • No conductor of an overhead lines shall have more than one joint
in a span • joints between conductors of overhead lines shall be mechanically
and electrically secure under the conditions of operation.
General Requirements Of Safety SAFETY REQUIREMENTS OF OVERHEAD LINES
Overhead lines shall have the following minimum factors of safety: • for metal supports - 1.5 • for mechanically processed concrete supports - 2.0 • for hand-moulded concrete supports - 2.5 • for wood supports - 3.0 • The minimum factor of safety for stay-wires,
guard-wires or bearer-wires shall be 2.5 based on the ultimate tensile strength of the wire.
General Requirements Of SafetySAFETY REQUIREMENTS OF OVERHEAD LINES
• Clearance above ground of the lowest conductor of overhead lines/Service lines: Across a street < 650 volts……………………………. 5.8 Mts. > 650 volts < 33000 volts........ 6.1 Mts.Along Any Street < 650 volts……………………………. 5.5 Mts. > 650 volts < 33000 volts........ 5.8 Mts.Elsewhere(other than the above) < 11000 volts…………………………….4.6 Mts.(bare conductor) < 11000 volts…………………………….4.0 Mts.(Insulated conductor) > 11000 volts < 33000 volts........5.2 Mts.• For lines of voltage exceeding 33000 volts, the clearance shall not be less than
5.2 mts+0.3 mts for every 33000 volts or part thereof by which the voltage of the line exceeds 33000 volts subject to a minimum clearance of 6.1mts along/across any street.
General Requirements Of Safety SAFETY REQUIREMENTS OF OVERHEAD LINES
Clearance from buildings of lines of voltage and service lines not exceeding 650 Volts: • An overhead line shall not cross over an existing building as far as
possible and no building shall be constructed under an existing overhead line.
• Where an overhead line of voltage not exceeding 650 V passes above or adjacent to or terminates on any building, minimum clearances from any accessible point, on the basis of maximum sag, to be observed are:
for any flat roof, open balcony, varandah roof and lean-to-roof- - when the line passes above the building a vertical clearance of 2.5 mtrs from the highest point -when the line passes adjacent to the building a horizontal clearance of 1.2 mtrs from the nearest point
General Requirements Of Safety SAFETY REQUIREMENTS OF OVERHEAD LINES
Clearance from buildings of lines of voltage and service lines not exceeding 650 Volts (contd…..): for pitched roof- - when the line passes above the building a vertical clearance of 2.5 mtrs immediately under the line - when the line passes adjacent to the building a horizontal clearance of 1.2 mtrs
General Requirements Of Safety SAFETY REQUIREMENTS OF OVERHEAD LINES
Clearance from buildings of lines of voltage and service lines not exceeding 650 Volts (contd…): • Any conductor so situated as to have a clearance less than
that specified above shall be adequately insulated and shall be attached at suitable intervals to a bare earthed bearer wire having a breaking strength of not less than 350 kg.
• The horizontal clearance shall be measured when the line is at a maximum deflection from the vertical due to wind pressure.
Explanation: For the purpose of this regulation, the expression "building" shall be deemed to include any structure, whether permanent or temporary.
General Requirements Of Safety SAFETY REQUIREMENTS OF OVERHEAD LINES
• Clearances from buildings of lines of voltage exceeding 650 V: An overhead line shall not cross over an existing building as far
as possible and no building shall be constructed under an existing overhead line.
Where an overhead line of voltage exceeding 650 V passes above or adjacent to any building or part of a building it shall have on the basis of maximum sag a vertical clearance above the highest part of the building immediately under such line, of not less than-
- for lines of voltages exceeding 650 Volts } 3.7 metres upto and including 33,000 Volts }
General Requirements Of Safety SAFETY REQUIREMENTS OF OVERHEAD LINES
• Clearance from buildings of lines of voltage exceeding 650 Volts (contd…):
• The horizontal clearance between the nearest conductor and any part of such building shall, on the basis of maximum deflection due to wind pressure, be not less than :
- For lines of voltages > 650 V &< 11000 V: 1.2 mtrs - For lines of voltages > 11,000 V & < 33000 V : 2.0 mtrs
General Requirements Of Safety SAFETY REQUIREMENTS OF OVERHEAD LINES
Lines crossing or approaching each other and lines crossing street and road: • Where an overhead line crosses or is in proximity to any
telecommunication line, the owner of either the overhead line or the telecommunication line, whoever lays his line later, shall arrange to provide for protective devices or guarding arrangement;
• Guarding shall be provided where lines of voltage not exceeding 33 kV cross a road or street;
• where an overhead line crosses or is in proximity to another overhead line, guarding arrangements shall be provided so as to guard against the possibility of their coming into contact with each other;
General Requirements Of SafetySAFETY REQUIREMENTS OF OVERHEAD LINES
Lines crossing or approaching each other and lines crossing street and road (contd…): • Minimum clearances in metres between lines
crossing each other: Nominal System Voltage High Voltage (11-66 kV) Low and Medium 2.44 11- 66kV 2.44
General Requirements Of SafetySAFETY REQUIREMENTS OF OVERHEAD LINES
Guarding: • Every guard-wire shall be connected with earth at each point at which its
electrical continuity is broken; • Every guard-wire shall have an actual breaking strength of not less than 635
kg and if made of iron or steel, shall be galvanised; • Every guard-wire or cross-connected systems of guard-wires shall have
sufficient current-carrying capacity to ensure them rendering dead, without risk of fusing of the guard-wire or wires, till the contact of any live wire has been removed.
Service lines from overhead lines: • No service-line or tapping shall be taken off an overhead line except at a
point of support: • Provided that the number of tappings per conductor shall not be more than
four in case of connections at voltage not exceeding 650 V.